Needleless injection device components, systems, and methods

ABSTRACT

Needleless injection device components, systems, and methods that involve features including an elongate shaft that has a working shaft comprising a working shaft proximal end, a working shaft distal end, and a working lumen extending between the working shaft proximal end and the working shaft distal end, an injection shaft including an injection shaft proximal end, an injection shaft distal end, and a needless injection orifice disposed through the sidewall at the injection shaft distal end, the injection shaft moveably disposed within the working lumen, and a tissue tensioner secured to the injection shaft at the injection shaft distal end and moveable relative to the working lumen, the tissue tensioner having an expandable surface capable of exhibiting an expanded state and a non-expanded state, the tissue tensioner in the expanded state being capable of tensioning luminal tissue for injection by the needless injection orifice.

PRIORITY CLAIM

This application is a continuation of U.S. patent application Ser. No.13/133,125, which was filed on Jun. 6, 2011, which claims the benefitfrom International Application No. PCT/US2009/006384, which was filed onDec. 4, 2009, which in turn claims priority under 35 USC §119(e) fromprovisional application Ser. No. 61/139,974, filed Dec. 22, 2008, byCrank, entitled ELASTIC ADAPTER FOR FLEXIBLE SCOPE COMPATIBLE INJECTIONDEVICE; provisional application Ser. No. 61/122,808, filed Dec. 16,2008, by Crank, entitled TWO-PIECE SIDE-FIRING JET INJECTION CATHETER;and provisional application Ser. No. 61/122,793, filed Dec. 16, 2008, byCrank, entitled URINARY TRACT CATHETER WITH SHAPEABLE TIP, each of theseapplications being incorporated herein by reference in its entirety.

FIELD OF THE INVENTION

The present invention relates generally to jet injection devices for thedelivery of therapeutic fluids to a treatment site. Described device andmethod embodiments involve a fitting such as an elastic adapter or otherremovable or permanent fitting to attach to a distal end of a shaft.Exemplary elastic adapters can be elastically stretched to fit over adistal end of a flexible scope or other medical device shaft. Optionallyand preferably an injection shaft such as a non-metal reinforcedpolymeric injection tube axially can be mounted alongside the fitting(e.g., elastic adapter) so as to be aligned parallel to the flexiblescope. In other embodiments, an adapter can be attached to an injectionshaft that is movably disposed within a lumen of a flexible scope orother medical device shaft.

BACKGROUND OF THE INVENTION

A wide variety of medical treatments are at least partially performedthrough the delivery and introduction of therapeutic compositions to atreatment location. In home or outpatient settings, typical deliverymethods can comprise oral delivery, via liquid or solid forms, as wellas a variety of inhalant style devices. In clinical or hospitalsettings, therapeutic fluids can be injected using needle based or insome minimally invasive procedures. The therapeutic fluid can bedelivered through a tubular device such as a catheter or endoscope basedsystems.

One way in which therapeutic fluids can be delivered internally isthrough the use a tube-like device configured to provide a jet-injectionof the therapeutic fluid at a desired treatment site. Generally, aremote injector is utilized to deliver the therapeutic fluid from anexternal reservoir located at a proximal end of the tube-like device sosuch administration can occur at a distal end of the tube-like device.Due to the relatively long travel length of the therapeutic fluidthrough the tube-like device, the remote injector must generally becapable of pressurizing the therapeutic fluid to pressures exceedingabout 2,000 psi. In order to accommodate these pressures, the tube-likedevices have been fabricated of alloys such as NiTi or stainless steelor with metal-reinforced polymers such as the braided tubes typicallyfound in catheters.

Currently a number of manufacturers make a variety of flexible scopes tonavigate the tortuous paths often found in the human body. Scopes suchas cytoscopes, endoscopes, ureteroscopes, choledoscopes, andhysteroscopes vary slightly in size and shape by brand. There isadvantage to using existing scopes for directing an injection device toa treatment site. Furthermore, there is advantage to controlling theoverall size of the injection system and scope so as minimize theinvasiveness of the procedure.

SUMMARY OF THE INVENTION

The invention involves needleless fluid injection devices. These devicesallow for localized delivery of therapeutic fluids that includebiologically active species and agents such as chemical and biochemicalagents at desired anatomical tissue locations including but not limitedto locations in the male or female urinary tract, e.g., urethra,prostate, bladder, bladder neck, etc. Exemplary devices can be designedto deliver fluid at various tissue locations, optionally also multipledifferent therapeutic fluids or multiple different tissue locations.

Embodiments of exemplary devices include a tissue tensioner attached(removably or otherwise, such as through a removable or non-removablefitting) to a distal end of a shaft, which may be a working shaft or aninjection shaft.

Other embodiments of exemplary devices include a fitting at a distal endof a shaft, e.g., a removable fitting or a non-removable fitting, toattach one distal end structure to another distal end structure. Afitting may be used, for example, to attach one distal end of a shaft(such as an injection shaft distal end) to another distal end of a shaft(such as a working shaft distal end). A distal end of a shaft may alsooptionally attach or be attached to a tissue tensioner optionallythrough the fitting or otherwise; the optional tissue tensioner may beassociated with (e.g., integrally connected to or removably attached to)the fitting, or may be associated with the injection shaft or theworking shaft apart from the fitting.

Still other exemplary embodiments include a tissue tensioner and afitting in the form of a tissue tensioner assembly. The fitting may be afitting that attaches to a distal end of a shaft (e.g., working shaft orinjection shaft), removably or non-removably.

In slightly more detail, certain exemplary devices include a tissuetensioner assembly comprising a tissue tensioner and a fitting, whereinthe fitting can be attached to a distal end of a shaft. The fitting canbe attached to a shaft, such as an injection shaft or a working shaft,in a removable or a non-removable, e.g., semi-permanent or permanent,fashion. As used herein, a fitting is considered “removable” if thefitting can be attached to a shaft in a manner sufficiently secure toallow the fitting to remain securely attached to the shaft during aninjection procedure without the fitting becoming undone, and the fittingcan be removed from the shaft without permanently damaging the shaft orthe fitting so at least one of the fitting or the shaft can be re-used.

In certain embodiments a tissue tensioner (e.g., as part of a tissuetensioner assembly) can be attached (removably or non-removably) to adistal end of an injection shaft, and the injection shaft can beinserted into a working lumen of a working shaft. Optionally a proximalend of the injection shaft can be inserted into a distal end of theworking lumen (alternately a distal end of the injection shaft can beinserted into a proximal end of the working lumen) and the injectionshaft can be placed within the length of the working lumen. A tissuetensioner assembly can be attached to the distal end of the injectionshaft, before or after inserting the injection shaft into the workingshaft. The tissue tensioner assembly may include an elongate actuatingshaft, lumen, or mechanism that extends to a proximal end; a proximalend of this elongate shaft, lumen, or actuating mechanism can also beinserted into a distal end of the working lumen.

In alternate embodiment a tissue tensioner (e.g., in the form of atissue tensioner assembly) can be attached to a distal end of a workingshaft, such as by use of a fitting and in a removable or non-removablefashion. An injection shaft can be associated with the working shaft;for example an injection shaft can be secured adjacent to the workingshaft, length-wise along an external surface of the working shaft,optionally by attachment to the same fitting that attaches to theworking shaft and to the tissue tensioner. Alternately an injectionshaft may be placed permanently, removably, integrally, securely, ormovably, within a working shaft, such as but not necessarily within aworking lumen.

Exemplary embodiments of described devices can include a non-metal,polymeric tube-like device (e.g., an “injection lumen”) for delivering atherapeutic fluid to a treatment site within a patient, attached(removably or non-removably) at a distal end to an elastic adapter (orother type of removable “fitting,” included but not limited to elasticadapters) sized to fit over a flexible scope (or “working shaft”) distalend. An exemplary fitting can be an elastic adapter in the form of asleeve-like device disposed about a distal end of the flexible scope.The exemplary elastic adapter may be manufactured from compliant orsemi-compliant material. The elastic adapter has a diameter less thanthe outer diameter of the scope associated with the injection treatment.The needle-less injection lumen (or “injection shaft”) may be attachedto the outer diameter of the elastic adapter or to an inner diameterwith the injection port (or “injection orifice”) disposed adjacent to anaperture (in the adapter). The elastic adapter may also include an upperrim to prevent the elastic adapter from axially sliding from the distalend of the scope.

In one embodiment, an elastic adapter may be a two layer device so as toinclude an inflation element (or “inflatable balloon” that can functionas a “tissue tensioner”). An inner elastic sleeve comprises a firstlayer. The first layer is elastically mounted about the distal end of aflexible scope (e.g., working shaft). As the flexible scope is stifferthan the elastic adapter, the elastic tension created by the stretchedelastic adapter does not impinge upon the scope. The second layer isattached around the outer diameter of the first layer to create aballoon. A balloon inflation lumen is disposed axially along a centralaperture (of the working shaft) with a first end in communication with amedia source such as compressed air or a fluid. A second end of theballoon inflation lumen is in communication with the space between thefirst and second layer. It is envisioned that the second layer mayradially overlap the axial ends of the first layer. In this embodiment,the injection lumen may be attached to the second layer.

It is further envisioned that in some embodiments the second layer mayonly partially surround the first layer. For example, the second layermaybe disposed eccentrically around the first layer leaving an axialsection of the first layer exposed. The injection lumen would thus beattached to the first layer along the exposed section. As the appositionballoon inflates the injection lumen can thus be positioned. Theeccentric geometry allows the apposition balloon to force the injectionlumen against the tissue chosen for treatment.

A non-metal, polymeric tube-like injection device (e.g., injectionshaft) can be fabricated using suitable high strength polymersincluding, for example, polyimide, polyetherimide available from GeneralElectric under the trade name Ultem® and linear aromatic polymers suchas PEEK™ available from Victrex plc. In some embodiments, a non-metal,polymeric tube-like device can be reinforced through the inclusion ofmaterials including nano-particles, clays and/or glass. In somepresently contemplated embodiments, the non-metal, polymeric tube-likedevice can be reinforced with one or more polymers such as, for example,tubes braided with Kevlar or other high-strength polymers. Thenon-metal, polymeric tube-like device can be fabricated so as to have aburst strength exceeding at least about 200 pounds per square inch,e.g., exceeding 1,000 or 2,000 psi, and in some embodiments, having aburst strength within a range of about 2,000 psi to about 5,000 psi. Thenon-metal, polymeric tube-like device can be fabricated so as to havedistention properties, wherein an orifice or jet port located at adistal end of the polymeric tube-like device retains its shape and/orsize without suffering swelling that can have a detrimental impact on afluid jet used to deliver the therapeutic fluid at the treatment site.

In one aspect the invention relates to a tissue tensioner assemblycapable of being connected to an elongate shaft. The tissue tensionerassembly includes: a tissue tensioner comprising an expandable surfacecapable of exhibiting an expanded state and a non-expanded state, and afitting connected to the tissue tensioner, the fitting capable ofattaching the tissue tensioner to a shaft.

In another aspect the invention relates to an elongate shaft capable ofinjecting fluid into tissue. The shaft includes: a working shaftcomprising a working shaft proximal end, a working shaft distal end, anda working lumen extending between the working shaft proximal end and theworking shaft distal end; an injection shaft comprising an injectionshaft proximal end and an injection shaft distal end, the injectionshaft moveably disposed within the working lumen; and a tissue tensionerlocated at the injection shaft distal end, the tissue tensionercomprising an expandable surface capable of exhibiting an expanded stateand a non-expanded state.

In yet another aspect the invention relates to an elongate shaft capableof injecting fluid into tissue. The shaft includes: a working shaftcomprising a working shaft proximal end and a working shaft distal end,and an injection shaft comprising an injection shaft proximal end and aninjection shaft distal end. The injection shaft distal end is attachedto the working shaft distal end by a removable fitting.

In yet another aspect the invention relates to a method of connecting aworking shaft distal end and an injection shaft distal end. The methodincludes: providing a fitting assembly comprising an injection shaftdistal end and a removable fitting capable of being attached to aworking shaft distal end, and attaching the removable fitting to theworking shaft distal end.

In yet another aspect the invention relates to a method of assembling ashaft and tissue tensioner. The method includes: providing a tissuetensioner assembly comprising a tissue tensioner comprising anexpandable surface capable of exhibiting an expanded state and anon-expanded state, and a fitting connected to the tissue tensioner; andattaching the fitting to an elongate shaft.

In another aspect the invention relates to a method of assembling ashaft and tissue tensioner. The method includes: providing an injectionshaft comprising an injection shaft proximal end, an injection shaftdistal end, and a tissue tensioner at the injection shaft distal end,the tissue tensioner comprising an expandable surface capable ofexhibiting an expanded state and a non-expanded state; providing aworking shaft comprising a working shaft distal end, a working shaftproximal end, and a working lumen extending between the working shaftdistal end and the working shaft proximal end; and inserting theinjection shaft proximal end into a distal end of the working lumen.

In another aspect the invention relates to a combination of two or morecomponents of a needleless injection system selected from: a console, aremovable pressure chamber, an injection shaft, a tissue tensioner, afitting, and a working shaft.

The above summary of the various representative embodiments of theinvention is not intended to describe each illustrated embodiment orevery implementation of the invention. Rather, the embodiments arechosen and described so that others skilled in the art may appreciateand understand the principles and practices of the invention. Thefigures in the detailed description that follows more particularlyexemplify these embodiments.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention may be more completely understood in consideration of thefollowing detailed description of various embodiments of the inventionin connection with the accompanying drawings, in which:

FIG. 1 is a perspective view of an embodiment of an elastic adapter witha therapeutic fluid delivery system for delivering a therapeutic fluidto a treatment location according to the present disclosure.

FIG. 2 is a perspective view of an embodiment of an elastic adapter witha therapeutic fluid delivery system disposed about a flexible scopeaccording to the present disclosure.

FIG. 3 is an alternate two layer embodiment of an elastic adapter with atherapeutic fluid delivery system for delivering a therapeutic fluiddisposed about a flexible scope according to the present disclosure.

FIG. 4 is a sectional view of the alternate embodiment of FIG. 3.

FIG. 5 is another alternate cross sectional view of the presentinvention.

FIG. 6 is another alternate cross sectional view of the presentinvention.

FIGS. 7A and 7B are side views of distal end components of shafts andassemblies as described.

FIG. 8 is an illustration of an exemplary needleless injection system asdescribed.

FIG. 9 illustrates options of combinations of systems as described.

While the invention is amenable to various modifications and alternativeforms, specifics thereof have been shown by way of example in thedrawings and will be described in detail. It should be understood,however, that the intention is not to limit the invention to theparticular embodiments described. On the contrary, the intention is tocover all modifications, equivalents, and alternatives.

DETAILED DESCRIPTION

In the following detailed description of the present invention, numerousspecific details are set forth in order to provide a thoroughunderstanding of the present invention. However, it will be obvious toone skilled in the art that the present invention may be practicedwithout these specific details. In other instances, well-known methods,procedures, and components have not been described in detail so as tonot unnecessarily obscure aspects of the present invention.

The invention relates to devices comprising a shaft for injecting afluid into tissue, such as a needleless injection device. Needlelessdevices as described generally include a distal end and a proximal end.As used herein, the “distal end” refers to a portion of the device thatis located internally within a patient's body during a treatmentprocedure, generally including the distal end of an elongate shaft. Ashaft distal end may include functional features that operate on fluidor tissue during use, such as one or more injection orifice, optionaldelivery head (end effector, nozzle, etc.) to house one or moreinjection orifices, optionally a tissue tensioner (as described),optionally a fitting to attach one component of a shaft distal end toone or more other component, optionally one or more of a light, opticalfeature, steering feature, etc. A “proximal end” of an exemplaryneedleless device can include an injector body or “console” that remainsexternal to the patient during use. An exemplary console can include ahousing that connects to or is otherwise (directly or indirectly) influid communication with the shaft. The console can include fluid thatcan be pressurized by a pressure source to cause the fluid to flowthrough the shaft for injection into tissue at the distal end.

A device can eject fluid from at least one injection orifice located atthe distal end of the shaft. Optionally, multiple injection orifices maybe located at one or more locations along a length of or about acircumference of a shaft distal end. Devices, systems, and methods asdescribed can be used to inject fluid (sometimes referred to as an“injectate” or “injection fluid,” which may be any type of fluid such asa therapeutic fluid) into tissue in a needleless manner whereby theinjectate passes as a pressurized fluid stream (or “jet”) through asurface of a tissue, penetrating without the use of a needle through thetissue surface and into the bulk of the tissue, and dispersing asparticles or droplets within the tissue below the tissue surface. Thiscontrasts with injections performed using a needle, whereby a hollowneedle structure is used to penetrate tissue to locate a hollow end ofthe needle within a tissue mass, below the tissue surface, after whichthe needle carries fluid into the bulk of the tissue and delivers thefluid at a relatively low pressure to the tissue in the form of a bodyor pool of fluid known as a bolus.

A fluid stream or jet ejected for injection into tissue by a needlelessinjection system can be of a size (e.g., diameter), velocity, pressure,and volume to allow the fluid stream to penetrate directly through atissue surface, then disperse within the tissue. The stream can beconsidered to be a relatively high velocity, high pressure, smalldiameter jet that after entry through a tissue surface disperses withinthe tissue, preferably as a multi-directional collection of particles(e.g., a “cloud”) or droplets within the bulk of the tissue. Exemplarypressures of a fluid at a pressure chamber can be at least 200 poundsper square inch (psi), e.g., from 300 to 5000 pounds per square inch.Without limiting the scope of the present description: when injectingbladder tissue a pressure of from 250 to 1000 psi can be effective,measured at the pressure chamber; when injecting prostate tissue apressure of from 3500 to 5000 psi can be effective, measured at thepressure chamber.

Exemplary needleless devices may be used for treating various physicalailments or conditions at any bodily tissue, for example to treat tissuethat contains or is within reach of injection through a body cavity orbody lumen, e.g., by accessing tissue through a body lumen, vessel, orcavity, and injecting tissue by placing an injection orifice within thelumen, vessel, or cavity. The type of tissue injected for treatment canbe any amenable tissue, especially tissue accessible through a bodylumen such as prostate tissue accessible through a urethra.

Exemplary needleless fluid delivery devices or systems can include aproximal end that includes a console, and an elongate shaft extendingfrom a proximal end in communication with the console to a distal end.The elongate shaft can include an injection shaft and an injectionlumen, optionally disposed permanently, semi-permanently, or loosely andmovably within or adjacent to a working lumen. A distal end of theinjection shaft can include one or more injection orifice fluidcommunication with the console, through an injection lumen.

A console generally can include a housing, a pressure chamber, and apressure source. A console can be of any configuration, size, or design,ranging from a small, hand-held design to a relatively larger floor ortable-mounted console. Optionally a console can include separate orseparable components such as a pressure chamber (e.g. “connectormember”) that can be attached between a housing and a proximal shaftend, used for an injection procedure, and detached and optionallydiscarded. A shaft (e.g., an injection shaft or a working shaft) canalso be attached to a console, pressure chamber, or connector member, ina manner to allow separation and optional re-attachment or disposalafter one or more use. With separable components, a shaft or pressurechamber can be attached to a console housing and used to inject a firstpatient or a first injectate; the shaft or pressure chamber (e.g.“connector member”) can then be discarded or sterilized. A second shaftor pressure chamber can be attached to the console to treat a secondpatient or the first patient with second injectate or another amount ofthe first injectate. The second patient or injectate can involveinjection and treatment of the same type of tissue as the first patientor injectate, or of a new type of tissue (e.g., prostate or bladder). Inthis manner, separable and optionally disposable shaft or pressurechamber components of a needleless injection system can allow a consolehousing to be used multiple times to inject the same or differentinjectates, to the same or different patients, and to the same ordifferent types of body tissue.

A console can include actuating features to control distal end features,e.g., for steering a steerable distal end of a steerable shaft, toactuate ejection of fluid, to move a moveable or extendable injectionshaft or one or more injection orifice relative to another shaftcomponent such as a working shaft, optional ports to connect a consolehousing to auxiliary devices, electronics such as controls, opticfeatures such as a lens, fiber optic, or electronic viewing mechanism toallow viewing through an optical feature (to view a location ofdelivery), and an actuating mechanism or pressure source for a tissuetensioner in the form of a mechanical tissue tensioner or an inflatableballoon. One or more attachment ports can optionally attach a console toan external and optionally remote component such as an external orremote pressure source, vacuum source, or an external or remote fluidreservoir to supply injectate or other fluid, such as to inflate aballoon. For example, a console (e.g., console housing or connectormember) may have a fluid port that attaches to a source of a fluid tosupply the fluid to the console, such as to a permanent or detachablepressure chamber. Embodiments of consoles can include a permanent orremovable pressure chamber and a pressure source capable of pressurizinga fluid contained in the pressure chamber to cause the fluid to flowfrom the console, through a lumen in the shaft, and then through aninjection orifice.

A fluid chamber can be a space (volume) at a proximal end of a devicesuch as at a console housing, useful to contain pressurized ornon-pressurized fluid, such as injectate or a gaseous or liquid fluid toinflate a balloon (e.g., tissue tensioner). Examples of specific typesof fluid chambers include fluid reservoirs and pressure chambers.Optionally a proximal end of a device may include one or multiple fluidreservoirs and pressure chambers.

A fluid reservoir is generally a type of fluid chamber that can containa fluid for a purpose of containing, transferring, holding, or storing afluid, such as a fixed volume fluid chamber, and may be included as apermanent or removable (attachable and detachable) component of aconsole.

A pressure chamber can be a type of fluid chamber for containing fluid(e.g., injectate) for a purpose of placing the fluid under pressure todeliver the fluid through a lumen to a distal end of a shaft forejection from an ejection orifice. Examples of pressure chambers includea syringe chamber and other variable volume spaces that can be used tocontain and pressurize a fluid. Examples of variable volume pressurechambers include spaces that can exhibit a variable volume based, e.g.,on a plunger, piston, bellows, or other mechanism for increasing ordecreasing the volume (and correspondingly decreasing or increasingpressure) within the variable volume chamber space. A pressure chambercan be pressurized by a pressure source attached to the plunger,bellows, or piston, etc., such that fluid contained in the pressurechamber is ejected under pressure, e.g., for priming a device, or forejecting fluid from an ejection orifice for injection or to produce acontrol force. A pressure source may be any source of energy (e.g.,mechanical, electrical, hydraulically derived, pneumatically derived,etc.) such as a spring, solenoid, compressed air, manual syringe,electric power, hydraulic, pneumatic pressure sources, etc. A pressurechamber may be a permanent or removable (attachable and detachable)component of a console.

Examples of consoles, console features and combinations of consolefeatures that can be useful according to the present description areidentified in Assignee's U.S. Pat. No. 8,262,605; and in Assignee'sfollowing copending patent applications: U.S. Pat. Publ. Nos.2009/0312696; 2011/0270216; 2011/0245762; and 2011/0264036, theentireties of these patent documents being incorporated herein byreference.

In communication with a proximal end of a device is an elongate shaftthat extends from the proximal end (i.e., from a proximal shaft end),that is optionally removably connected to the console (or a component ofthe console such as, a removable pressure chamber), to a distal end thatcan be placed in a patient during an injection procedure. A shaft can beof various designs, minimally including an injection lumen to carryinjectate from a proximal end of the device to a distal end of theinjection shaft. Shafts for needleless devices as described are alsodescribed in Assignee's copending U.S. Pat. Publ. No. 2011/0282318.

An injection shaft minimally includes an injection lumen incommunication with an injection orifice. The injection shaft can includestructure such as sidewalls that define the injection lumen, thesidewalls being of sufficient strength to withstand operating pressuressufficient to deliver injectate from the injection orifice at anelevated pressure sufficient to cause the injectate to be ejected fromthe injection orifice to penetrate a tissue surface and become injectedand into and dispersed below the tissue surface, as described herein.Exemplary elevated pressures (“injection pressures”) may be at least200, e.g. 1,000, or 2,000 pounds per square inch or greater as measuredat the distal end of the injection lumen, or at the pressure chamber. Aninjection shaft may be of a flexible material (e.g., a metal orpolymeric tube) that can withstand such injection pressure, and may beprepared from exemplary materials capable of withstanding pressure of aninjection, e.g., nitinol, stainless steel, reinforced (e.g., braided)polymer, as also described elsewhere herein.

A basic version of a useful shaft as described can be an “injectionshaft” that includes a proximal end, a distal end, a sidewall thatdefines an internal lumen (“injection lumen”), and at least oneinjection orifice at the distal end in connection with the injectionlumen.

An injection shaft can be any elongate structure capable of deliveringfluid to a distal end of the injection shaft at a pressure suitable toinject tissue, as described. Exemplary injection shaft structuresinclude relatively flexible hollow bodies having a distal end, aproximal end, sidewalls extending between the ends, an internal lumendefined by interior surfaces of the sidewall. The injection lumen is incommunication with one or more injection orifice at the distal end; theinjection orifice may be as described herein, such as an aperture orbore in an injection shaft sidewall, an aperture or bore in a nozzle,end effector, injection head, or other structure in communication withthe injection lumen.

An exemplary injection shaft can be in the form of a non-metal,polymeric tube-like device and can be fabricated using suitable highstrength polymers including, for example, polyimide, polyetherimideavailable from General Electric under the trade name Ultem® and lineararomatic polymers such as PEEK™ available from Victrex plc fortransporting the treatment fluid to the treatment area. In someembodiments, the non-metal, polymeric tube-like device can be reinforcedthrough the inclusion of materials including nano-particles, claysand/or glass. In some presently contemplated embodiments, the non-metal,polymeric tube-like device can be reinforced with one or more polymerssuch as, for example, tubes braided with Kevlar or other high-strengthpolymers. The non-metal, polymeric tube-like device can be fabricated soas to have a burst strength exceeding at least about 200, e.g., 1,000 or2,000 psi and in some embodiments, having a burst strength within arange of about 2,000 psi to about 5,000 psi. The non-metal, polymerictube-like device can be fabricated so as to have distention properties,wherein one or more orifices or jet ports located at a distal end of thepolymeric tube-like device retains its shape and/or size withoutsuffering swelling that can have a detrimental impact on a fluid jetused to deliver the therapeutic fluid at the treatment site. See, e.g.,U.S. Pat. Publ. No. 2008/0119823.

An exemplary injection shaft can include a sidewall that defines anouter shaft surface and an inner injector lumen, these being ofcontinuous and relatively uniform dimensions of inner diameter, outerdiameter, and wall thickness, along an entire length of the injectionshaft. Alternately, an injection shaft, injector lumen, or sidewall, maychange dimensions (e.g., wall thickness) along the length of theinjection shaft, with a larger wall thickness (e.g., greater outerdiameter) at a proximal end and a thinner wall thickness (e.g., reducedouter diameter) at the distal end. An example of an inner diameter of aninjection shaft (i.e., a diameter of an injection lumen) can be greaterthan 0.020 inches, e.g., from 0.022 to 0.030 inches (for a lumen made ofpolyetheretherketone, or “PEEK”); exemplary outer diameters for the sameexemplary injection shaft may be at least 0.032 inches e.g., from 0.034to 0.045 inches. (An inner dimension of a fitting for placement on suchan injection shaft may be, e.g., in the range from about 0.03 to about0.05 inches.) A length of an injection shaft can be any length thatfunctions to place a proximal end at a console and a distal end at adesired tissue location; exemplary lengths can be from as little as 15inches if the console is a hand-held console, to as long as 100 inchesif the console is floor based or table based.

An injection shaft can be a component of a shaft of a useful needlelessinjection device or system. Other shaft components may includeadditional elongate shaft structures with desired functionality, asingle example being a device referred to herein as “medical deviceshaft” or a “working shaft,” which can be used to securely or moveablysupport or house an injection shaft. For instance, an injection shaftcan be incorporated permanently or movably (e.g., removably) against(alongside) or within (e.g., in a “working lumen” of) a working shaft.In exemplary embodiments an injection shaft can be loosely contained ina working lumen of a working shaft to allow movement of the injectionshaft length-wise and rotationally relative to the working shaft; aninjection shaft may be capable of moving longitudinally within a workinglumen to allow the injection lumen to be extended distally from an openend of a working lumen at a distal end of the working shaft.

An example of a “working shaft” or “medical device shaft” can be a shaftthat is useful in conjunction with an injection shaft, to manipulate andplace the injection orifice of an injection shaft at a desired locationfor treatment of tissue. A “working shaft” or “medical device shaft” canfunction to support the injection shaft and can optionally andpreferably include any of a variety of optional functionalities such assteerability, an optical function, a tissue tensioner, or combinationsof these, in addition to supporting the injection shaft.

An example of a particularly preferred working shaft can includefeatures of a typical cystoscope, endoscope, ureteroscope, choledoscope,hysteroscope, catheter (e.g., urinary catheter), or the like, or othersimilar type of medical device shaft, including one or more feature offlexibility, an optical function, a steerable distal shaft end, and aworking lumen. A working lumen can be sized to loosely house or containthe injection shaft, preferably in a manner to allow the injection shaftto be moved lengthwise and rotationally within the working lumen,relative to the working lumen, such as to allow the injection lumen (andoptionally an attached tissue tensioner) to be extended from an openingat a distal end of the working lumen, at a distal end of the workingshaft. A typical diameter (or other dimension) of a working lumenextending along a length of a distal end of a working shaft can be inthe range from about 1 to about 3 millimeters. A typical length ofworking shaft for placement of a distal end at a location of the urinarytract can be, e.g., from 15 to 25 centimeters. A typical outsidediameter of a working shaft may be, for example, from about 4 to about10 millimeters.

As used herein, the term “flexible shaft” refers to a shaft (e.g., aninjection shaft or a working shaft) that is sufficiently pliable toallow bending and flexing that allow the shaft to be inserted throughthe meatus or an external incision, into the urethra or another bodylumen, and to allow a portion of a distal end of the shaft to be guidedinto a body lumen or body cavity such as a urethra and optionally thebladder neck or bladder, as can be done with a Foley catheter. Aflexible shaft can be sufficiently soft and pliable to conform orpartially conform to a patient's anatomy, such as would a Foley-typecatheter. A “steerable” shaft is a type of a flexible shaft having adistal end that can be maneuvered directionally (e.g., bent or curved)from a proximal end; steerable shaft distal ends are sometimes featuresof endoscopes and other medical device shafts.

Optionally, a shaft of a device as described may also be malleable, or“shapeable,” meaning that a shaft distal end, or portion thereof, can beof a material capable of being shaped to a form, and to remain in thatform during use, such as for insertion into a body lumen, untilre-formed. A shaft or a shaft component, such as a working shaft or aninjection shaft, can include a malleable component such as a bendablemetal wire, coil, ribbon, tube, or the like, capable of being shaped,used without substantial deformation, and re-shaped. A malleable distalend can allow a distal end to be shaped by a user to assist in placementof the distal end through a body lumen such as a urinary tract, at adesired location. In some methods of treatment, there may bedifficulties or challenges in passing a shaft distal end through a bodylumen, or to place the distal end in contact with tissue for injection.A malleable shaft distal end, e.g., of an injection shaft in particular,e.g., used in conjunction with a working shaft within which themalleable injection shaft distal end is moveably disposed, or inconjunction with a working shaft adjacent to which the malleableinjection shaft distal end is disposed, may assist in overcoming suchpotential difficulties. The malleable distal end tip may be formed by auser to a desired curve or bend, before or after placement in a workingchannel or adjacent to a working shaft; the working shaft may beinserted into a body lumen such as a urethra, and the formed, malleableinjection shaft distal end may be extended from or placed adjacent tothe working shaft with a shape that improves the ability to position theinjection shaft or an injection orifice thereof, at tissue forinjection. A shapeable portion may vary in stiffness, length,resilience, material, radiopacity, etc., and may be of any malleablematerial such as a polymer, metal, or polymer-metal composite.

A distal end of an injection shaft includes one or multiple injectionorifices for ejecting fluid within a body of a patient. An injectionorifice can be any form of opening, aperture, or orifice, such as anaperture or bore in an injection shaft sidewall, or an aperture or borein a nozzle, end effector, injection head, or other structure incommunication with an injection lumen. Injection orifices can be locatedat relative locations and orientations along a length or circumferenceof an injection shaft distal end to result in ejection and distributionof ejected fluid in different directions (e.g., circumferentiallyrelative to the shaft), optionally or alternately at different distancesalong the length of the injection shaft. An injection orifice can bedirected at any angle relative to a longitudinal axis of a shaft, suchas perpendicular, angled toward a distal end, or angled toward aproximal end.

An injection orifice may have any useful size (e.g., length anddiameter) to produce a fluid stream of ejected fluid that can penetratea tissue surface to become injected into tissue. Examples of a usefulrange of diameter of an injection orifice may be from about 0.001 to0.05 inches, e.g., from 0.001 to 0.010 inches, depending on factors suchas desired injection parameters (injection depth, volume, pressure, exitvelocity, etc.) and the type and size (e.g., depth) of tissue beinginjected. An injection orifice may be larger or smaller than aninjection lumen leading to the injection orifice, if desired, to affectthe exit velocity of the jet of injectate from the injection orifice.Examples of useful orifice shapes may include features such as aventuri, a continuous uniform diameter along the length of an orifice, afunnel-shape, etc.

According to exemplary injection methods and devices, an injectionorifice may be located on a proximal side of a distal end tip at alocation that allows the injection orifice and adjacent injection shaftsidewall to contact a tissue surface as a longitudinal axis of a shaftthat contains the injection orifice is positioned in an orientation thatis parallel to the tissue surface. These device embodiments aresometimes referred to as “side-fire” devices, herein. As used herein, a“distal end tip” can be considered a location of a distal end of aninjection shaft that is the farthest (most distal) feature of theinjection shaft distal end.

In certain embodiments of “side-fire” devices an injection orifice canbe located a distance away from a distal end tip on a proximal side ofthe distal end tip so the injection orifice is located to contact tissuefor injection by placing the shaft sidewall in contact with tissue.Examples of injection orifice locations for these embodiments can belocations along a distal end of a shaft that are in the range from about1 to about 40 millimeters from the distal end tip, on a proximal side ofthe distal end tip, e.g., such as a distance in the range from about 1to about 25 millimeters from the distal end tip.

According to certain exemplary devices, a distal end of a shaft(injection shaft, working shaft, or the like) can include a tissuetensioner, the tissue tensioner optionally being attached to the distalend of the shaft by a fitting that is attached to the tissue tensioner,such as as part of a tissue tensioner assembly. A tissue tensioner canbe located at a distal end of a shaft, somewhat near to an injectionorifice, e.g., to be within a body lumen such as a urethra, e.g., aprostatic urethra, and near the injection orifice when the distal end ofthe shaft is installed in a patient for injection. For example a tissuetensioner can be located at a length-wise location along an injectionshaft that is the same length-wise location as the length-wise locationof an injection orifice.

A tissue tensioner can comprise an expandable surface, e.g., acontinuous expandable surface such as an inflatable balloon, or anon-continuous expandable surface such as an expandable metal (orplastic) cage or the like. The expandable surface can exhibit anexpanded state and a non-expanded state. According to exemplary methods,a tissue tensioner can be placed in a body lumen in a non-expanded stateand expanded within the lumen to the expanded state. In the expandedstate, the tissue tensioner contacts an internal surface of the lumen tohold the distal end of the shaft and an associated injection orifice inplace relative to desired tissue for injection. The tissue tensioner canoptionally produce tension or strain on the tissue in a manner that canaffect the manner in which an injected fluid stream penetrates thetissue surface and becomes distributed in the tissue upon injection. Atissue tensioner can facilitate a good result upon injection of fluidthrough luminal tissue by ensuring that the luminal tissue is fixed andincludes a desired amount of tension for receiving an injection.

Depending on the configuration of an injection orifice at a shaft of adevice, or at an injector head, a tissue tensioner can be used to placea desired portion of tissue in (e.g., direct) contact with an injectionorifice, i.e., a surface that contains an injection orifice.Alternately, a tissue tensioner can place a desired portion of tissue ata desired distance away from an injection orifice, e.g., in the instanceof an injector head that includes two surfaces with a recessed surfaceincluding an injection orifice. The distance, if any, between aninjection orifice and tissue, at injection, can be selected to affectproperties of the injection, e.g., to affect the distance an injectatepenetrates into tissue, the size of droplets formed beneath the tissuesurface, and the pattern over which droplets of injectate are dispersedthroughout tissue when injected. Other factors can also be adjusted toaffect properties of the injection such as pressure and volume ofinjectate, size and shape of the injection orifice, etc.

Examples of tissue tensioners include inflatable balloons located at ashaft distal end near an injection orifice (e.g., at the samelength-wise location as the injection orifice), and mechanicallyextendable structures such as paddles, protrusions, levers, metal orplastic cages, metal or plastic springs or spirals, and the like, any ofwhich can be include a surface that can be extended (e.g., mechanically)from a distal end of a working shaft or injection shaft to placepressure on internal tissue, e.g., on urethral tissue within theprostatic urethra or other luminal tissue. Tissue tensioners, deviceshafts, and related mechanisms and methods are described in Applicants'copending U.S. Patent Publ. No. 2006-0129125 and U.S. Ser. No.12/087,231, filed Jun. 27, 2008, by Copa et al., entitled DEVICES,SYSTEMS, AND RELATED METHODS FOR DELIVERY OF FLUID TO TISSUE, theentireties of both of these being incorporated herein by reference.

A balloon or a mechanically extendable tissue tensioner can be inflatedor extended at a location that is approximately at a length along adistal end of a shaft that is near an injection orifice, e.g., at alength-wise location that is the same as the length-wise location of theinjection orifice. When used within a lumen such as a urethra, thetissue tensioner can push luminal tissue (e.g., urethral tissue) awayfrom the distal end of the shaft in a manner that causes the luminaltissue and an injection orifice to contact each other. This can be done,for example, by a balloon expanding from an opposite side of a shaftrelative to an injection orifice to place pressure on luminal tissuelocated opposite from an injection orifice and to cause the injectionorifice to contact adjacent luminal tissue, optionally to producepressure, strain, or tension on the luminal tissue opposite of theballoon. A mechanical tensioner may be extended from a distal end of ashaft by use of an actuating mechanism such as a mechanical connectionbetween the tissue tensioner and the proximal end of a device, such asat a working shaft proximal end. An inflatable balloon may be extendedfrom a distal end of a shaft by inflating the balloon with pressurizedfluid such as air or another gaseous or liquid fluid.

A distal end of a device as described may optionally include a fittingthat functions to attach together two or more components of a distalend. Exemplary fittings can be any device or structure that engages andattaches to a distal end of an injection shaft or a working shaft. Afitting can be a component of or attached to another feature asdescribed herein, such as a tissue tensioner, an injection shaft, or aworking shaft.

Optionally, a fitting can be attached to an outer surface of aninjection shaft or a working shaft; such a fitting can be in the form ofa complete or partial ring or cylindrical surface that includes aninterior dimension that fits around an outer surface (or portionthereof) of the injection shaft or working shaft.

Optionally, a surface of an injection shaft or a working shaft caninclude an opposing or complementary shape, form, or surface, thatengages a shape or form of the fitting; examples of complementary oropposing surfaces can include opposing threaded surfaces; opposingsnap-fit engagement elements; opposing elements of a mechanical detentengagement, a mechanical spring-engagement; a mechanical key-fitengagement, and the like. Other examples of fittings include opposingpress-fit surfaces, and elastic band surfaces. These and like types offittings can be prepared from plastic or metal materials. Elastic bandfittings can be prepared from one or more elastic materials such asrubber (natural or synthetic), elastic polymer, silicone, latex, and thelike.

Certain preferred embodiments of fittings can be orientation specific toallow an engagement at only a single orientation, e.g., a fitting may be“keyed. As a single example, a fitting in the form of a cylindrical orpartially cylindrical receiver (or receptor) sized to engage a shaft maybe keyed (opposing surface structures of the fitting and the shaft mayallow engagement in only a single rotational orientation). A keyedfitting can be used to allow an engagement between two attached shaftelements to occur only at a desired orientation between elements of theshafts, e.g.,: a fastener that attaches an injection shaft to a workingshaft may be keyed to require desired orientation between an injectionorifice of the injection shaft and the working shaft, for example toallow viewing of the injection shaft or injection orifice or to requiredesired positioning of the injection orifice relative to a tissuetensioner associated with the working shaft; alternately a fitting of atissue tensioner assembly may be keyed to require placement of thetissue tensioner assembly at a desired orientation relative to a workingshaft or an injection lumen (and injection orifice).

A fitting can be part of an assembly (e.g., a “fitting assembly”) thatincludes the fitting removably or non-removably attached to anothercomponent such as a tissue tensioner, an injection shaft, or a workingshaft. An example of a fitting assembly can be a fitting assembly thatincludes a fitting attached to an injection shaft distal end, whereinthe fitting removably attaches to a working shaft. See FIG. 1. Thefitting assembly can include one of any of the described fittingsattached securely to the injection shaft, and situated to allow thefitting to be attached to a working shaft. Exemplary fittings include anelongate receptor that includes one or more of: threads; a snap-fitengagement; a mechanical detent engagement; a spring; a keyed engagementsurface; or an elastic band, capable of being placed on a distal end ofa working shaft. In use, the fitting assembly including the injectionshaft distal end securely attached to the fitting assembly, can beremovably attached to the distal end of the working shaft by attachingthe fitting to the working shaft distal end. If desired, the fitting canbe keyed to require a determined orientation between the working shaftand the injection shaft. If the fitting is an elastic band, the elasticband can be stretched over a working shaft distal end. Alternately, ifthe fitting is of a different type, such as a mechanical (threaded,etc.) fitting, the fitting can be attached mechanically. In injectionmethods, the fitting assembly can be removably attached to a distal endof a working shaft, the working shaft can be placed within a tissuelumen, an optional tissue tensioner can be expanded, fluid can beejected from the injection shaft to inject tissue, the distal end of theworking shaft can be removed from the patient, and the fitting assemblycan be removed from the distal end of the working shaft. The workingshaft can be re-used in later procedures, and the fitting assemblyincluding the injection shaft may be disposed of or re-used. Thisembodiment of a fitting assembly can optionally include a tissuetensioner that becomes located about the working shaft distal end whenthe fitting assembly is placed on the working shaft distal end. SeeFIGS. 1 through 6.

Another example of a fitting assembly can be a fitting assembly thatincludes a tissue tensioner (i.e., a tissue tensioner assembly), andattached to a fitting, wherein the fitting can be removably ornon-removably attached to an injection shaft distal end. The tissuetensioner assembly can include one of any of the described fittingsattached securely to a tissue tensioner, and situated to allow thefitting to be attached to a distal end of a shaft such as a workingshaft or an injection shaft. Exemplary fittings include an elongatereceptor that includes one or more of: threads; a snap-fit engagement; amechanical detent engagement; a spring; a keyed engagement surface; oran elastic band; capable of being placed on a distal end of a workingshaft or injection shaft. If desired, the fitting can be keyed torequire a pre-determined rotational orientation between the tissuetensioner and the working shaft or injection shaft. In use, the fittingof the tissue tensioner assembly can be removably (or non-removably)attached to the distal end of an injection shaft or a working shaft. Ifthe fitting is an elastic band, for example, the elastic band can beplaced (e.g., stretched) around the injection shaft distal end. SeeFIGS. 7A and 7B, showing such a tissue tensioner assembly removablyattached to a distal end of an injection lumen.

A tissue tensioner assembly that includes a fitting that can beremovably attached to a distal end of a working shaft can, in use, beused according to steps that include: removably attaching the tissuetensioner assembly to a distal end of a working shaft, placing theworking shaft (the distal end of the shaft also being associated with aninjection shaft) within a tissue lumen, expanding the tissue tensioner,ejecting fluid from an injection shaft associated with the working shaftto inject tissue, and removing the distal end of the working shaft fromthe patient. The tissue tensioner assembly can be removed from thedistal end of the working shaft. The working shaft can be re-used inlater procedures, and the tissue tensioner assembly may be disposed ofor re-used. In this embodiment, the tissue tensioner assembly mayoptionally be securely attached to a distal end of an injection shaftand in use the injection shaft becomes disposed adjacent to an exteriorsurface, and along a length of, the working shaft.

A tissue tensioner assembly that includes a fitting that can be attached(removably or non-removably, such as by adhesive or by integralconstruction) to a distal end of an injection lumen can, in use, be usedaccording to steps that include: placing the injection shaft within aworking lumen of a working shaft such as by loading the proximal end ofthe injection shaft into the distal end of the working lumen oralternately by loading the distal end of the injection shaft into theproximal end of the working lumen, attaching the tissue tensionerassembly to a distal end of an injection shaft (optionally with theinjection shaft already being loaded into the working lumen), placingthe working shaft distal end (and injection shaft and tissue tensioner)within a tissue lumen, expanding the tissue tensioner, ejecting fluidfrom the injection shaft to inject tissue, and removing the distal endof the working shaft (and injection shaft and tissue tensioner assembly)from the patient. The tissue tensioner assembly can be removed from thedistal end of the injection shaft; alternately, the entire injectionshaft and tissue tensioner assembly can be removed from the workingshaft. The working shaft can be re-used in later procedures, and thetissue tensioner assembly, working shaft, or both, may be disposed of orre-used.

FIGS. 7A and 7B illustrate an embodiment of a tissue tensioner assembly.Assembly 110 includes fastener 111 that includes an elongate receptorsized to receive a distal end of injection shaft 120 (includinginjection orifices 122 and distal end tip 124). Rings or bands 112 canbe elastic or non-elastic, plastic, metal, rubber, etc., bands toremovably secure assembly 110 to the distal end of injection shaft 120.Tissue tensioner 114, illustrated as an inflatable balloon in anon-expanded state, is securely attached or optionally integral withfastener 111. Inflation lumen 116 is in fluid communication with tissuetensioner (balloon) 114 in a manner to allow gas or liquid fluid (e.g.,air) to be inserted into tissue tensioner 114 to inflate and expandtissue tensioner 114. Optionally a proximal end of inflation lumen 116can be accessible at the proximal end of a working lumen that can beassociated with injection lumen 120 and tissue tensioner assembly 110.

Referring to FIG. 7B, assembly 110 is shown attached to a distal end ofinjection shaft 120, which is in turn disposed within working lumen 132of working shaft 130. This distal end configuration comprising injectionshaft 120, working shaft 130, and tissue tensioner assembly 110, is anexample of a useful side-fire injection shaft configuration movablydisposed within a working lumen. Side-firing injection orifices 122 areapposed by tissue tensioner (balloon) 114; when balloon 114 is expandedwithin a body lumen, side-firing injection orifices 122 are pressuredagainst internal luminal tissue.

Still referring to FIGS. 7A and 7B, tissue tensioner 114 is aninflatable balloon but the tissue tensioner may alternately be of othertypes, such as an expandable cage. Also, fitting 111 is illustrated tobe removable from injection shaft 120, but could alternately bepermanent, semi-permanent, or non-removable, or could even be absent inthat tissue tensioner 114 could optionally be integral with or otherwiseattached to the distal end of injection shaft 120. In still alternateembodiments, inflation lumen 116 could be incorporated into injectionshaft 120.

In injection methods, a distal end as shown in FIGS. 7A and 7B can beprepared by attaching the tissue tensioner assembly 110 (removably orpermanently) to the distal end of injection shaft 120, as illustrated.The tissue tensioner assembly 110 and injection shaft 120 can beinserted into a distal end of working lumen 132 and passed throughworking lumen 132 to extend from the distal end of working lumen 132 toa proximal end (not shown) of working lumen 132. Working shaft 130 canbe placed within a tissue lumen (e.g., urethra). Tissue tensioner 114can be expanded to secure placement of injection orifices 122 againstinternal luminal tissue. Fluid can be ejected from injection orifices122 to inject tissue. The distal end of working shaft 130 and injectionshaft 120 can be removed from the patient. In embodiments whereinfitting 111 is removable, tissue tensioner assembly 110 can be removedfrom the distal end of injection shaft 120. Working shaft 130 can bere-used in later injection procedures. Injection shaft 120 may beremoved from working lumen 132 and may optionally be re-used ordiscarded.

A needleless fluid delivery system 100 is illustrated generally in FIG.1 as attached to elastic adapter (i.e., a fitting in the form of anelastic band) 10. The elastic adapter 10 is comprised of compliant orsemi-complaint elastic material. The elastic adapter 10 defines acentral aperture 12 through which a flexible scope (e.g., a workinglumen) is inserted. The elastic adapter 10 has an inner face 14 and anouter face 16 separated by material thickness 18. It is envisioned thatthe elastic adapter 10 could be disposed about the distal end of acystoscope, ureteroscope, choledoscope, endoscope or hysteroscope (e.g.,any type of (working shaft). The amount of elastic tension about theflexible scope may be varied by selecting the thickness and/or type ofthe elastic material (and the size, e.g., inner diameter, of the elasticadapter). Furthermore, the axial length 20 of elastic adapter 10 mayinclude designated bending areas or areas of greater elastic tension soas not to interfere with the efficiency of the flexible scope. Theneedless fluid delivery system 100 is attached to the elastic adapter 10axially at connection region 22. In alternative embodiments it isenvisioned that the needless fluid delivery system 100 may be connectedby radial bands attached to the outer face 16 of the elastic adapter 10or is disposed within central aperture 12 of the elastic adapter 10.

Needleless fluid delivery system 100 can comprise an injector (e.g., ata proximal end, not shown), an applicator lumen (“injection lumen”) 104,and an injection orifice 102. The injector (e.g., including a console asdescribed herein) can be as simple as manually activated syringe, or cancomprise an automated injector including a user interface and aconnector member. A connector member at a proximal end or other fluidchamber can include a therapeutic fluid supply and the user interfacecan comprise an input means for selectively delivering a pressurizedfluid through the connector member. Representative input means caninclude foot pedal, switches, buttons or a touch-screen capable ofreceiving touch commands as well as displaying system informationincluding a mode of operation as well as operating parameters. Theapplicator lumen 104 can comprise a non-metal, polymeric tube likedevice having a proximal attachment end 106 and a distal treatment end(or injection shaft distal end) 108. A non-metal, polymeric tube likedevice can have a tube length that corresponds to a type of treatment tobe performed within a patient's body. For example, when a non-metal,polymeric tube like device is configured to perform a cystoscope orendoscopic procedure, the tube length can range from about 18 to about72 inches in length. Once the distal treatment end 108, and morespecifically, the administration orifice 102 is positioned with respectto the treatment location, the injector can be actuated so as to begindelivery of a therapeutic fluid. In positioning the needless fluiddelivery system 100 at treatment location, it will be understood that amedical professional frequently employs a medical imaging system suchas, for example, computer axial tomography (CAT), magnetic resonanceimaging (MRI), or in the case of treatment of a prostate gland, anexemplary imaging means is transrectal ultrasound (TRUS) so as toachieve the desired position of administration Orifice 102. Anotherimaging means is by direct vision of the distal end of the inserteddevice, optionally the injection shaft or injection orifice, throughdirect vision by use of an endoscope.

As illustrated in FIG. 2, elastic adapter 10 is disposed about aflexible scope (e.g., working shaft) 30 such as a cystoscope to delivertherapeutic fluid to a treatment location, such as, for example, theurinary bladder, urethra, prostate, etc. Cystoscope 30 can include aworking channel (working lumen) 36, a fiber optic light source 32 andlens 38 such that a medical professional can verify the distal treatmentend 34 is positioned proximate the treatment location. It is envisionedthat elastic adapter 10 could include an upper face that caps a portionof the distal treatment end 34 of the cystoscope 30. However, any capportion must be positioned so as not to interfere with the cystoscopeoperation.

An alternate two-layer embodiment of an elastic adapter (or fitting)200, is illustrated in FIGS. 3-6. A cystoscope 30 (or other workingshaft) is positioned within elastic adapter 200 to deliver therapeuticfluid to a treatment location, such as, for example, the urinarybladder, urethra, prostate, etc. Cystoscope 30 can include a workingchannel (working lumen) 36, a fiber optic light source 32, and lens 38such that a medical professional can verify the distal treatment end 34is positioned proximate the treatment location. Needleless fluiddelivery system 100 can comprise an injector (not shown), an applicatorlumen (“injection lumen”) 104, and an injection orifice 102.

The elastic adapter 200 may be a two layer device so as to include aninflation element 202. An inner elastic sleeve comprises a first layer204. The first layer 204 is elastically mounted about the distal end 34of the flexible scope 30. As the flexible scope 30 is stiffer than theelastic adapter 200, the elastic tension created by the stretchedelastic adapter does not impinge upon the scope. The second layer 206 isattached around the outer diameter of the first layer 204 to create aballoon 210. A balloon inflation lumen 208 is disposed axially along acentral aperture 212 with a first end (proximal end) in communicationwith a media source such as compressed air or a fluid. A second end 212of the balloon inflation lumen 208 is in communication with the spacebetween the first layer 204 and second layer 206. It is envisioned thatthe second layer 206 may radially overlap the axial ends of the firstlayer 204. The apposition balloon 210 is thus defined by the secondlayer 206 overlap of the first layer 204.

It is further envisioned that in some embodiments the second layer 206may only partially surround the first layer 204 as illustrated in FIG.4. For example, the second layer 206 maybe disposed eccentrically aroundthe first layer 204 leaving an axial section of the first layer 204exposed. The injection lumen (injection shaft) 104 would thus beattached to the first layer 204 along the exposed section. As theapposition balloon 210 inflates the injection lumen 104 can thus bepositioned (within a body lumen). The eccentric geometry allows theapposition balloon 210 to force the injection lumen 104 against thetissue chosen for treatment.

In an additional embodiment, the injection lumen 104 would be attachedbetween the first layer 204 and second layer 206, as illustrated in FIG.5 or be attached to the second layer 206 as illustrated in FIG. 6.

In operation, the elastic adapter 200 would be placed about the distalend 34 of the flexible scope 30 by stretching the first layer 204.Elastic tension of the first layer 204 will maintain the position of theneedleless injection system 100 relative to the flexible scope 30. Theflexible scope 30 would be advanced to a treatment location at whichtime the balloon 210 would be filled through inflation lumen 212.Selectively inflating balloon 210 will assist in proper positioning ofthe injection orifice 102. Treatment may include providing ajet-injection of the therapeutic fluid through the injection orifice 102at a desired treatment site. Generally, a remote injector is utilized todeliver the therapeutic fluid from an external reservoir located at aproximal end of the tube-like device 100. After treatment is complete,the balloon 210 is deflated and the flexible scope 30 withdrawn.

Another exemplary embodiment of a needleless injection system accordingto the present description is illustrated at FIG. 8. Device 500 includesa handle 502 and distal shaft end 504 of working shaft 503, whichincludes injection shaft 508 disposed within working lumen 518. Theproximal end of the devices includes handle 502 of a scope that connectsto working shaft 503 (e.g., of a cystoscope, endoscope, catheter, orother medical device shaft), including features useful for manipulatingor operating features at distal end 504. Handle 502 includes: fiberoptic light source 516; steering actuator 514, which can be manipulatedto cause the steerable distal end of device 500 to move in at two ormore dimensions); viewing lens 520 that allows viewing through fiberoptic cable 510; and port 524, which allows for connection of a fluidsource to handle 502. Articulation for steering of distal end 504 isindicated in dashed lines.

Still referring to FIG. 8, body 512 connects to working shaft 503, whichincludes lumens and mechanisms that connect features of proximal endhandle 502 to distal end 504. Working lumen 518 is a hollow lumen orchannel that extends within working shaft 503 and supports and containsinjection shaft 508 in a manner that allows injection shaft 508 to movelongitudinally along the length of working shaft 503, to allow thedistal end of injection shaft 508 to extend from end opening 522 ofworking lumen 518. Working shaft 503 also includes fiber optic 510 and asteering mechanism (not shown) that allows steering (deflecting) ofdistal end 504 by movement of actuator 514. Light source 516 transmitslight to distal end 504 by fiber optic 510.

Distal end 504 includes end opening 522 of working lumen 518 from whichcan be extended injection shaft 508, which includes at least oneinjection orifice. Also distal end 504 can be steered to allow movementof the tip of working shaft distal end 504, in coordination withextension of injection shaft 508, based on viewing through fiber optic510, to deliver a fluid with accurate placement at a desired tissuelocation. The distal end of injection shaft 508 can be any design asdescribed herein, e.g.: can include multiple injection orifices atdifferent length-wise or circumferential locations; can include a tissuetensioner for apposition of an injection orifice against tissue; etc. Asillustrated, fluid stream 509 is shown being ejected from an injectionorifice (not shown); tissue tensioner (balloon) 511 is located on anopposite side of injection lumen 508 from the injection orifice.

While FIG. 8 illustrates an embodiment of a needleless injection systemhaving an elongate shaft that includes an injection shaft disposedwithin a working lumen of a working shaft, other embodiments arealternately useful, such as embodiments of distal shaft ends of FIGS. 1through 6, including an injection shaft dispose on an exterior of aworking shaft, and an optional tissue tensioner disposed about a distalend of the working shaft.

Also illustrated at FIG. 8 is shaft 546 extending between port 524 ofhandle 502 and console 542. Console 542 includes pressure chamber 540and pressure source 544.

With any of the above features of fluid delivery devices, a device couldinclude an electronic process control system that can be programmed tomake fluid deliveries having various locations, volumes, and otherinjection properties such as depth and degree (e.g., shape and distance)of dispersion and size of particles of fluid.

A needleless injection system can be use to perform treatment methods bysteps that include one or more of the following: providing a needlelessinjection device substantially as described herein; inserting a distalend of a shaft of the fluid delivery device into a patient, e.g.,through the meatus and into the urethra; navigating the distal end untilan injection orifice at the distal end of the shaft is positioned at adesired delivery site. An injection shaft distal end can be positionedwith a sidewall in contact with tissue, with a longitudinal axis of theshaft in line with (e.g., parallel to) tissue; an optional tissuetensioner can be used to cause a sidewall of the injection shaft distalend to contact and be pressed against the tissue surface to cause aninjection orifice to contact the tissue surface for injection.

By any of the described methods, multiple injection orifices can providethe ability to place one or more different fluids at multiple locationsof the urethra, prostate, bladder, or bladder neck, or other tissue,etc. Other treatment locations can include a rectal treatment location,a gastrointestinal treatment location, a nasal treatment location, abronchial treatment location, or an esophageal treatment location.Features of devices described herein, such as optical features,steerable shafts, tissue tensioners, and the ability to deliver multipledifferent types of fluid, allow for improved control over the locationof injection or instillation of a fluid.

According to certain exemplary fluid delivery procedures of theinvention, fluid such as ethanol or a biologically active agent can bedelivered to the bladder, urethra, prostate, or bladder neck, etc., in amanner that causes the fluid to be injected into the tissue using aneedleless delivery orifice.

Devices of the present description can be useful to treat of varioustissues, including of the urinary tract, in females or males. Forexample, devices as described may be useful to inject the bladder,bladder neck, the urethral tissue itself or the external sphincter, orfor transurethral injection of the prostate in a male. In otherembodiments, a fluid may be injected into tissue of the urinary tract(e.g., bladder, urethra, kidneys, ureters, prostate, etc.) such asindividual or combination treatments using drugs or other therapeuticagents, e.g., botulinum toxin (“botox”), an antiandrogen, a neurotoxin,among others as will be understood. One advantage of injection of anactive pharmaceutical agent at a location of use is the placement of theagent to avoid systemic side effects. Specific examples of activepharmaceutical agents that may be injected include botulinum toxin typesA through G; 5-alpha reductase inhibitors such as dutasteride andfinasteride; alpha blockers such as alfuzosin, doxazosin, prazosin,tamsulosin hydrochloride, terazosin, ethanol, to treat BPH; or any ofvarious antibiotics (e.g., to treat prostatitis) and analgesics.

FIG. 9 illustrates components of combination 620 of the invention. Anydifferent combination of components can be included in a system or set.The components include console 600, optional “connector member” orexternal, removable pressure chamber 602, multiple varieties ofinjection shaft attachments (i) through (iv) that can be separatelyattached to console 600 or removable pressure chamber 602, and a singleworking shaft 610 including handle 612. Console or console housing 600can be as described, and includes at least a pressure source. Port 601allows connection to optional removable pressure chamber 602, which canbe connected at a proximal end to port 601, and has distal end 605 thatcan be connected to a proximal end of an injection shaft attachment.Optional port 603 of pressure chamber 602 can be used to insert fluidinto pressure chamber 602. Each of injection shaft attachments (i),(ii), (iii), and (iv), is exemplary and for purposes of illustration ofexemplary combinations. Each includes a proximal end (611) that canremovably attach to console or console housing 600, optionally byremovably attaching to connector member 602 at distal end 605. Eachinjection shaft attachment also includes one or more injection orifice606 at a distal end 604, connected through an inflation lumen (notshown) to the proximal end. Each injection orifice as illustrated is ona proximal side of a distal end tip 607.

An optional component of combination 620 is working shaft 610, which maybe as described herein, e.g., including handle 612, port 622 suitable tointroduce an injection shaft into working lumen 616 of working shaft614, optional steerable distal end 618, and an optional optical feature(not shown).

Another optional component of a combination 620 can be a fastenerassembly 620 having fastener 624 (e.g., an elastic fastener or otherform of elongate receptor, optionally keyed) capable of attaching to adistal end of working shaft 624, and another fastener 626 (e.g., anelastic fastener or other form of elongate receptor, optionally keyed)capable of attaching to a distal end of an injection shaft.

A combination can include any one or combination of injection shaftattachments as shown or otherwise described herein. An exemplaryinjection shaft attachment can include any one or more of: a side-firedistal end with an elongate receptor 609 that may be an elongate elasticreceptor or a non-elastic elongate receptor capable of attaching to anoutside surface of working shaft distal end 618, and that is alsoremovably attached to distal end 604 (i); a side-fire distal end with anoptional malleable distal end feature (not shown) and multiple injectionorifices along a length of the distal end (ii); a distal end with asingle injection orifice near distal end tip 607, including tissuetensioner (e.g., inflatable balloon) 613 attached (e.g., securely) tothe injection shaft distal end on the side opposite the injectionorifice, and inflation lumen (or mechanical actuator, if the tissuetensioner is mechanically actuated) 615 extending alongside theinjection shaft to a proximal end (iii); and, a distal end with a singleinjection orifice near distal end tip 607, including combined fittingand tissue tensioner 615 attached (e.g., securely) to the injectionshaft distal end on the side opposite the injection orifice, aninflation lumen (not shown) extending alongside or within the injectionshaft to a proximal end, and the combined fitting and tissue tensionerbeing an elastic or non-elastic fitting sized to fit at the distal end618 of working shaft 614.

While the invention is amenable to various modifications and alternativeforms, specifics thereof have been shown by way of example in thedrawings and will be described in detail. It should be understood,however, that the intention is not to limit the invention to theparticular embodiments described. On the contrary, the intention is tocover all modifications, equivalents, and alternatives.

1. An elongate shaft capable of injecting fluid into tissue, theelongate shaft comprising: a working shaft comprising a working shaftproximal end, a working shaft distal end, and a working lumen extendingbetween the working shaft proximal end and the working shaft distal end,an injection shaft comprising an injection shaft proximal end, aninjection shaft distal end, and a needless injection orifice disposedthrough the sidewall at the injection shaft distal end, the injectionshaft moveably disposed within the working lumen, and a tissue tensionersecured to the injection shaft at the injection shaft distal end andmoveable relative to the working lumen, the tissue tensioner comprisingan expandable surface capable of exhibiting an expanded state and anon-expanded state, the tissue tensioner in the expanded state beingcapable of tensioning luminal tissue for injection by the needlessinjection orifice.
 2. The elongate shaft according to claim 1, whereinthe tissue tensioner is secured to the injection shaft distal end by anadhesive.
 3. The elongate shaft according to claim 1, wherein the tissuetensioner is secured to the injection shaft distal end by a removablefitting selected from the group consisting of an elastic band, asnap-fit engagement, a press-fit engagement, a threaded engagement, akey-fit engagement, and combinations of these fittings.
 4. The elongateshaft according to claim 1, wherein the tissue tensioner comprises aninflatable balloon and further comprises an inflation lumen incommunication with the inflatable balloon.
 5. The elongate shaftaccording to claim 1, wherein the working shaft comprises a steerabledistal end.
 6. The elongate shaft according to claim 1, wherein theneedless injection orifice is located along a length of the injectionshaft distal end at a distance in the range from about 1 to about 40millimeters on a proximal side of a distal end tip.
 7. The elongateshaft according to claim 1, wherein the injection shaft comprises aninjection lumen extending between the injection shaft proximal end andthe injection shaft distal end, the injection lumen being in fluidcommunication with the needless injection orifice and wherein theinjection lumen is capable of withstanding a pressure of at least 200pounds per square inch.
 8. A method of placing an elongate shaft distalend of a needless injection device in a body lumen, the methodcomprising: providing a tissue tensioner assembly, the tissue tensionerassembly capable of being connected to the elongate shaft of theneedleless injection device, the tissue tensioner assembly comprising: atissue tensioner comprising an expandable surface capable of exhibitingan expanded state and a non-expanded state, and a fitting connected tothe tissue tensioner, the fitting capable of attaching the tissuetensioner to the distal end of the elongate shaft at a location to allowthe tissue tensioner in the expanded state to tension luminal tissue forinjection by a needleless injection orifice of the needless injectiondevice; placing the shaft distal end in a body lumen with the tissuetensioner in the non-expanded state, and expanding the tissue tensionerwithin the body lumen.
 9. The method according to claim 8, wherein thestep of expanding the tissue tensioner within the body lumen moves theneedless injection orifice towards body tissue to be injected.
 10. Themethod according to claim 8, wherein the tissue tensioner is secured tothe elongate shaft distal end by an adhesive.
 11. The method accordingto claim 8, wherein the tissue tensioner is secured to the elongateshaft distal end by a removable fitting selected from the groupconsisting of an elastic band, a snap-fit engagement, a press-fitengagement, a threaded engagement, a key-fit engagement, andcombinations of these fittings.
 12. The method according to claim 8,wherein the tissue tensioner comprises an inflatable balloon and furthercomprises an inflation lumen in communication with the inflatableballoon.
 13. A method of injecting tissue, the method comprising:providing an elongate shaft comprising: a working shaft having a workingshaft proximal end, a working shaft distal end, and a working lumenextending between the working shaft proximal end and the working shaftdistal end, an injection shaft comprising an injection shaft proximalend, an injection shaft distal end, and a needless injection orificedisposed through the sidewall at the injection shaft distal end, theinjection shaft moveably disposed within the working lumen, and a tissuetensioner secured to the injection shaft at the injection shaft distalend and moveable relative to the working lumen, the tissue tensionercomprising an expandable surface capable of exhibiting an expanded stateand a non-expanded state, the tissue tensioner in the expanded statebeing capable of tensioning luminal tissue for injection by the needlessinjection orifice; placing the shaft distal end in a body lumen with thetissue tensioner in the non-expanded state; expanding the tissuetensioner within the body lumen, and ejecting a fluid stream from theinjection lumen such that the injection stream penetrates tissue. 14.The method according to claim 13, wherein the step of expanding thetissue tensioner within the body lumen moves the needless injectionorifice towards the tissue to be injected.
 15. The method according toclaim 13, wherein the tissue tensioner is secured to the injection shaftdistal end by an adhesive.
 16. The method according to claim 13, whereinthe tissue tensioner is secured to the injection shaft distal end by aremovable fitting selected from the group consisting of an elastic band,a snap-fit engagement, a press-fit engagement, a threaded engagement, akey-fit engagement, and combinations of these fittings.
 17. The methodaccording to claim 13, wherein the tissue tensioner comprises aninflatable balloon and further comprises an inflation lumen incommunication with the inflatable balloon.
 18. The method according toclaim 13, wherein the working shaft comprises a steerable distal end.19. The method according to claim 13, wherein the needless injectionorifice is located along a length of the injection shaft distal end at adistance in the range from about 1 to about 40 millimeters on a proximalside of a distal end tip.
 20. The method according to claim 13, whereinthe injection shaft comprises an injection lumen extending between theinjection shaft proximal end and the injection shaft distal end, theinjection lumen being in fluid communication with the needless injectionorifice and wherein the injection lumen is capable of withstanding apressure of at least 200 pounds per square inch.